Crosstalk between innate-immunity human microglia and adaptive-immunity Tregs in Alzheimer's disease

阿尔茨海默病中先天免疫人类小胶质细胞和适应性免疫 Tregs 之间的串扰

基本信息

批准号：
10515987
负责人：
STUART A LIPTON
金额：
$ 44.38万
依托单位：
SCRIPPS RESEARCH INSTITUTE, THE
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-09-01 至 2027-05-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10515987
关键词：
Adaptive Immune System Affect Alzheimer&apos s Disease Alzheimer&apos s disease brain Amyloid beta-Protein Anti-Inflammatory Agents Astrocytes Binding Blood Blood donor Bone Marrow Brain Cell Death Cells Cessation of life Coculture Techniques Cues Development Disease Electrophysiology (science)Excitatory Amino Acid Antagonists Exposure to Fluorescent Probes Functional disorder Future Gene Expression Glutamate Receptor Glutamates Human Immune Immune response Inflammation Inflammatory Inflammatory Response Interleukin-10 Ion Channel Knowledge Lead Light Measures Memantine Methods Microglia Mutation N-Methylaspartate NMDA receptor A1 Natural Immunity Neuraxis Neurodegenerative Disorders Neurons Pathogenesis Pathway interactions Persons Prevalence Protocols documentation Publishing Receptor Activation Regulatory T-Lymphocyte Reporting Signal Transduction Stimulus Synapses System T-Lymphocyte Testing Time Transforming Growth Factor beta Western Blotting Work Yolk Sac acquired immunity adaptive immunity alpha synuclein base cell motility chemokine cytokine exposed human population gene correction human old age (65+)induced pluripotent stem cell insight macrophage migration misfolded protein neuroinflammation neuronal survival novel therapeutic intervention patch clamp prevent receptor expression recruit response

项目摘要

Title: Crosstalk between innate-immunity human microglia and adaptive-immunity Tregs in Alzheimer’s disease (RFA-AG-22-017) Project Summary This application is in response to RFA-AG-22-017, looking at crosstalk between innate and acquired immunity in Alzheimer’s disease (AD). AD affects ~5% of people over age 65, and its prevalence is increasing. Neuroinflammation has been described in neurodegenerative disorders, and particularly in AD. Microglial cells, the resident macrophages of the central nervous system (CNS), respond to different pro- inflammatory stimuli by releasing glutamate, as well as pro-inflammatory cytokines and chemokines. Glutamate release from astrocytes and microglia has also been observed after exposure to Aβ and to αSyn, proteins that are misfolded in AD. T lymphocytes, express several NMDA-type glutamate receptors (NMDARs), and we have also detected their expression in Tregs, whose activity can reportedly ameliorate neurodegenerative disorders. Using patch-clamp recording, our Preliminary Studies show for the first time the presence of functional NMDAR-operated ion channels on human Tregs. Glutamate is known to affect T cell migration and activation; however, the effect of glutamate on Treg migration/activation has not been reported, and, specifically, it is not known how this might impact neurons in AD brain. We hypothesize that glutamate exposure of Tregs will limit their release of anti-inflammatory and neuroprotective factors, thus contributing to neuronal synaptic damage and cell loss. This crosstalk between the innate and acquired immune system may represent a significant contributor to the pathogenesis of AD. We have recently developed a protocol for generating human iPSC-derived microglia (hiMG) following a yolk sac differentiation method (brain microglia originate from the yolk sac and not from the bone marrow). We will test our hypothesis using a platform of hiPSC-derived microglia (hiMG), human Tregs (isolated from normal blood donors), and hiPSC-derived cerebrocortical neurons (hiN) bearing AD mutations (vs. their isogenic/gene- corrected controls). Using this platform, we show in our Preliminary Studies that hiMG release glutamate following activation with oligomeric Aβ and αSyn. We will systematically investigate the mechanism of the activation of Tregs by glutamate released by hiMG, and the effect of this cellular crosstalk on neuronal function. We will evaluate neuronal synaptic integrity and function as well as neuronal survival. The knowledge gained from this study will shed light on the effect of glutamate on neuroinflammation in a human context, and will provide insight into the effect of crosstalk between human microglial and Tregs in stimulating Treg activation. Thus, the work may aid in the development of future novel therapeutic interventions based on human microglial and Treg function and interaction.

标题：阿尔茨海默病中先天免疫人类小胶质细胞和适应性免疫 Tregs 之间的串扰疾病 (RFA-AG-22-017) 项目概要此应用程序是为了响应 RFA-AG-22-017，着眼于先天和后天之间的串扰阿尔茨海默病 (AD) 的免疫力影响约 5% 的 65 岁以上人群，其患病率是神经退行性疾病中的神经炎症有所增加，特别是 AD 中。小胶质细胞是中枢神经系统 (CNS) 的常驻巨噬细胞，对不同的亲通过释放谷氨酸以及促炎细胞因子和趋化因子来刺激炎症。在暴露于 Aβ 和 αSyn 后，也观察到星形胶质细胞和小胶质细胞的释放，这些蛋白质 AD 中 T 淋巴细胞错误折叠，表达多种 NMDA 型谷氨酸受体 (NMDAR)，我们还检测到它们在 Tregs 中的表达，据报道，Tregs 的活性可以改善神经退行性疾病使用膜片钳记录，我们的初步研究首次显示了疾病的存在。已知人类 Tregs 上的功能性 NMDAR 操作离子通道会影响 T 细胞迁移和迁移。激活；然而，谷氨酸对 Treg 迁移/激活的影响尚未报道，并且，具体来说，尚不清楚这可能如何影响 AD 大脑中的神经元。我们发现 Tregs 的谷氨酸暴露会限制它们释放抗炎和神经保护因素，从而导致神经元突触损伤和细胞损失。先天性和获得性免疫系统可能是 AD 发病机制的重要贡献者。最近开发了一种在卵黄囊后生成人类 iPSC 衍生小胶质细胞 (hiMG) 的方案分化方法（脑小胶质细胞起源于卵黄囊而不是骨髓）。我们的假设使用 hiPSC 衍生的小胶质细胞 (hiMG)、人类 Tregs（从正常血液中分离）的平台供体）和携带 AD 突变的 hiPSC 衍生的脑皮质神经元（hiN）（与其同基因/基因相比）使用该平台，我们在初步研究中表明 hiMG 释放谷氨酸。用寡聚 Aβ 和 αSyn 激活后，我们将最终研究其机制。 hiMG 释放的谷氨酸激活 Tregs，以及这种细胞串扰对神经元的影响我们将评估神经元突触的完整性和功能以及神经元的存活率。从这项研究中获得的知识将揭示谷氨酸对神经炎症的影响人类背景，并将深入了解人类小胶质细胞和 Tregs 之间的串扰效应因此，这项工作可能有助于开发未来的治疗性新型干预措施。基于人类小胶质细胞和 Treg 的功能和相互作用。